Self aligned metal gates on high-k dielectrics

ABSTRACT

A method for forming a transistor including a self aligned metal gate is provided. According to various method embodiments, a high-k gate dielectric is formed on a substrate and a sacrificial carbon gate is formed on the gate dielectric. Sacrificial carbon sidewall spacers are formed adjacent to the sacrificial carbon gate, and source/drain regions for the transistor are formed using the sacrificial carbon sidewall spacers to define the source/drain regions. The sacrificial carbon sidewall spacers are replaced with non-carbon sidewall spacers, and the sacrificial carbon gate is replaced with a desired metal gate material to provide the desired metal gate material on the gate dielectric. Various embodiments form source/drain extensions after removing the carbon sidewall spacers and before replacing with non-carbon sidewall spacers. An etch barrier is used in various embodiments to separate the sacrificial carbon gate from the sacrificial carbon sidewall spacers. Other aspects and embodiments are provided herein.

This application is a divisional of U.S. application Ser. No. 11/216,375, filed Aug. 31, 2005, which is incorporated herein by reference.

TECHNICAL FIELD

This disclosure relates generally to integrated circuits, and more particularly, to transistor structures and methods of formation.

BACKGROUND

Many integrated circuits include a metal-oxide-semiconductor field-effect transistor, or “MOSFET” for short, which includes a gate, a source, a drain, and a body. An issue in MOSFET design involves the structure and composition of its gate. Some early MOSFET designs included aluminum gates, and later MOSFET designs used polysilicon gates because of the desire for a self-aligned gate, the tendency of aluminum to diffuse through the underlying insulative layer, and because of problems that the relatively low melting temperature of aluminum caused with annealing processes. Polysilicon can be doped to act as a conductor, but with significantly more electrical resistance than aluminum. This higher resistance can be ameliorated somewhat by silicidation. However, the higher resistance of even the salicided polysilicon gates combines with inherent integrated-circuit capacitances to cause significant delays in conducting signals from one circuit point to another, ultimately limiting how fast integrated circuits operate.

Currently, the semiconductor industry relies on the ability to reduce or scale the dimensions of the basic components, including the gate dielectric, of its transistor devices to obtain lower power consumption and higher performance. To reduce transistor size, the thickness of the gate dielectric is reduced in proportion to the shrinkage of the gate length. Increased scaling and other requirements in microelectronic devices have created the need to use other dielectric materials as gate dielectrics, in particular dielectrics with higher dielectric constants (k) to replace the conventional use of various combinations of SiO₂, Si₃N₄ and SiON. Practical higher dielectric constant (k) materials have the properties of high permittivity, thermal stability, high film and surface quality and smoothness, low hysteresis characteristics, low leakage current density, and long term reliability. However, polysilicon gates and high-k dielectric materials have interface instability issues.

Scaling of transistors also requires shallow, difficult-to-form, source/drain extensions. In some conventional processes, source/drain extensions are formed, and then sidewall spacers are used to define the source/drain regions. The subsequent high-dose implant and high-temperature anneal of the source/drain regions can negatively impact the lightly doped source/drain extensions.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A–1D illustrate a process for forming a self aligned metal gate for a transistor structure, according to various embodiments of the present subject matter.

FIG. 2 illustrates an embodiment of a method for forming a self aligned metal gate on high-k gate dielectrics.

FIG. 3 illustrates a wafer, upon which the transistors with self aligned metal gates can be fabricated according to embodiments of the present subject matter.

FIG. 4 illustrates a simplified block diagram of a high-level organization of an electronic system that includes the transistor with the self aligned metal gate, according to various embodiments.

FIG. 5 illustrates a simplified block diagram of a high-level organization of an electronic system that includes transistors with self aligned metal gates, according to various embodiments.

DETAILED DESCRIPTION

The following detailed description refers to the accompanying drawings which show, by way of illustration, specific aspects and embodiments in which the present invention may be practiced. The various embodiments are not necessarily mutually exclusive, as aspects of one embodiment can be combined with aspects of another embodiment. Other embodiments may be utilized and structural, logical, and electrical changes may be made without departing from the scope of the present invention. In the following description, the terms “wafer” and “substrate” are used interchangeably to refer generally to any structure on which integrated circuits are formed, and also to such structures during various stages of integrated circuit fabrication. Both terms include doped and undoped semiconductors, epitaxial layers of a semiconductor on a supporting semiconductor or insulating material, combinations of such layers, as well as other such structures that are known in the art. The terms “horizontal” and “vertical”, as well as prepositions such as “on”, “over” and “under” are used in relation to the conventional plane or surface of a wafer or substrate, regardless of the orientation of the wafer or substrate. References to “an”, “one”, or “various” embodiments in this disclosure are not necessarily to the same embodiment, and such references contemplate more than one embodiment. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, along with the full scope of equivalents to which such claims are entitled.

Disclosed herein, among other things, is a transistor device structure with a self aligned metal gate in contact with a high-k dielectric. A self aligned metal gate structure is formed on a high-k gate dielectric by the replacement of amorphous carbon gates with metals. A planar transistor structure is formed with a carbon gate, the carbon is removed by plasma oxidation, and is replaced by a metal gate. Disposable carbon sidewall spacers are also used to ensure the formation of shallow lightly doped source/drain extensions.

Those of skill in the art will understand that the term high-k dielectric refers to a dielectric material having a dielectric constant greater than that of silicon dioxide. That is, a high-k dielectric has a dielectric constant greater than 4. A transistor device structure with a high-k gate dielectric and a self-aligned metal gate increases the capacitance and reduces the resistance of integrated circuits, which is useful for nanoscale integrated circuits. Additionally, the transistor device disclosed herein is capable of being manufactured with gates engineered to have differing work functions. Thus, in CMOS designs, a transistor metal gate is able to provide a desired work function (within 0.2 eV of the Ec of silicon) for NMOS devices and a desired work function (within 0.2 eV of the Ev of silicon) for PMOS devices.

The self aligned metal gates replace a sacrificial carbon gate formed on a high-k gate dielectric. Various embodiments replace the sacrificial carbon gate with aluminum (Al), tungsten (W), molybdenum (Mo), gold (Au), silver (Ag), gold alloy, silver alloy, copper (Cu), platinum (Pt), rhenium (Re), ruthenium (Ru), rhodium (Rh), nickel (Ni), osmium (Os), palladium (Pd), iridium (Ir), cobalt (Co), germanium (Ge) or metallic nitrides such as WN, TiN or TaN covered by metals.

Various embodiments provide the self aligned gate on high-k dielectrics such as AlO_(X), LaAlO₃, HfAlO₃, Pr₂O₃-based lanthanide oxide, HfSiON, Zr—Sn—Ti—O, ZrON, HfO₂/Hf, ZrAl_(X)O_(Y), ZrTiO₄, Zr-doped Ta oxide, HfO₂—Si₃N₄, lanthanide oxide, TiAlO_(X), LaAlO_(X), La₂Hf₂O₇, HfTaO amorphous lanthanide doped TiO_(x), TiO₂, HfO₂, CrTiO₃, ZrO₂, Y₂O₃, Gd₂O₃, praseodymium oxide, amorphous ZrO_(X)N_(Y), Y—Si—O, LaAlO₃, amorphous lanthanide-doped TiO_(X), HfO₂/La₂O₃ nanolaminates, La₂O₃/Hf₂O₃ nanolaminates, HfO₂/ZrO₂ nanolaminates, lanthanide oxide/zirconium oxide nanolaminates, lanthanide oxide/hafnium oxide nanolaminates, TiO₂/CeO₂ nanolaminates, PrO_(X)/ZrO₂ nanolaminates, Hf₃N₄/HfO₂ nanolaminates, and Zr₃N₄/ZrO₂ nanolaminates.

Device Structure

FIGS. 1A–1D illustrate a process for forming a self aligned metal gate for a transistor structure, according to various embodiments of the present subject matter. FIG. 1A illustrates a substrate 101 with a high-k gate dielectric 110 formed thereon. The substrate 101 can be a semiconductor wafer as well as structures having one or more insulative, semi-insulative, conductive, or semiconductive layers and materials. Thus, for example, the substrate can include silicon-on-insulator, silicon-on-sapphire, and other structures upon which semiconductor devices are formed.

In various embodiments, the high-k gate dielectric 110 layer includes a dielectric such as AlO_(X), LaAlO₃, HfAlO₃, Pr₂O₃-based lanthanide oxide, HfSiON, Zr—Sn—Ti—O, ZrON, Hf₂/Hf, ZrAl_(X)O_(Y), ZrTiO₄, Zr-doped Ta oxide, HfO₂—Si₃N₄, lanthanide oxide, TiAlO_(X), LaAlO_(X), La₂Hf₂O₇, HfTaO amorphous lanthanide doped TiO_(x), TiO₂, HfO₂, CrTiO₃, ZrO₂, Y₂O₃, Gd₂O₃, praseodymium oxide, amorphous ZrO_(X)N_(Y), Y—Si—O, LaAlO₃, amorphous lanthanide-doped TiO_(X), HfO₂/La₂O₃ nanolaminates, La₂O₃/Hf₂O₃ nanolaminates, HfO₂/ZrO₂ nanolaminates, lanthanide oxide/zirconium oxide nanolaminates, lanthanide oxide/hafnium oxide nanolaminates, TiO₂/CeO₂ nanolaminates, PrO_(X)/ZrO₂ nanolaminates, Hf₃N₄/HfO₂ nanolaminates, Zr₃N₄/ZrO₂ nanolaminates, and the like. The use of the high-k dielectric increases the capacitance, which is useful for nanoscale integrated circuits.

In FIG. 1A, a sacrificial gate 103 is formed of amorphous carbon on the high-k gate dielectric 110. In various embodiments, an etch barrier 108 is formed over the sacrificial gate and the dielectric. The etch barrier 108 includes silicon nitride or aluminum oxide, and can be formed using a deposition process, according to various embodiments. Sacrificial sidewall spacers 106 are added adjacent the sacrificial gate 103. In various embodiments, the spacers 106 are formed of amorphous carbon by deposition and conventional direct etch techniques. An ion implantation 130 and high temperature anneal are used to form source/drain regions 102 in areas defined by the sacrificial sidewall spacers 106. These annealing temperatures can pose problems for aluminum gates and other metal gates that have melting temperatures less than the anneal temperature for the source/drain regions.

In FIG. 1B, the sacrificial sidewall spacers (106 in FIG. 1A) have been removed. Various embodiments use a plasma oxidation process to remove the sacrificial sidewall spacers. In addition, the etch barrier (108 in FIG. 1A) has been removed. In various embodiments, a light dose ion implantation 140 is used to form source/drain extensions 142 in the substrate 101. The extensions 142 can be annealed at lower temperatures and in shorter times than the more heavily doped source/drain regions 102. According to various embodiments, forming source/drain extensions for the transistor includes doping the substrate to a depth of 30 nm or less.

In FIG. 1C, conventional, or non-carbon, sidewall spacers 156 are formed and the whole structure is back filled with an oxide fill 158, such as silicon dioxide, and planarized. A planarization procedure, such as chemical-mechanical polishing, can be used to provide an even surface. In various embodiments, the conventional sidewall spacers are formed with silicon nitride.

In FIG. 1D, the sacrificial gate (103 in FIG. 1C) is removed and replaced by the deposition of a metal layer 160. In various embodiments, the sacrificial gate is removed using a plasma oxidation process. Various deposition processes, such as evaporation, sputtering or chemical vapor deposition, may be used to form the metal layer 160. The structure is planarized (not shown) using a planarization procedure, such as chemical-mechanical polishing, resulting in the self aligned metal gate over the high-k gate dielectric insulator 110. Drain and source contacts (not shown) can be formed, as well as interconnects to other transistors or components, using conventional techniques. Another heat treatment may occur after packaging the integrated circuit in a protective housing in an attempt to minimize the resistivity of the metal gate contacts and other metal interconnections.

The metal gate replacement technique, as disclosed herein, can be applied to MOS devices, as generally illustrated in FIG. 1, as well as to form metal floating gates and/or metal control gates in nonvolatile devices. Additionally, various high-k dielectrics can be used between the floating gate and the substrate, and between the control gate and the floating gate in these nonvolatile devices.

Thus, FIGS. 1A–1D illustrate two replacement processes for the formation of planar self aligned metal gate transistors, one for disposable sidewall spacers and the other for the gate material itself.

Self Aligned Metal Gate Method

FIG. 2 illustrates an embodiment of a method 200 for forming a self aligned metal gate on high-k gate dielectrics. According to various method embodiments, a high-k gate dielectric is formed on a substrate at 202 and a sacrificial carbon gate is formed on the gate dielectric at 204. Sacrificial carbon sidewall spacers are formed adjacent to the sacrificial carbon gate at 206, and source/drain regions for the transistor are formed at 208, using the sacrificial carbon sidewall spacers to define the source/drain regions. The sacrificial carbon sidewall spacers are replaced with non-carbon sidewall spacers at 210, and the sacrificial carbon gate is replaced with a desired metal gate material at 212, to provide the desired metal gate material on the gate dielectric.

Various embodiments form source/drain extensions after removing the carbon sidewall spacers and before replacing with non-carbon sidewall spacers. An etch barrier is used in various embodiments to separate the sacrificial carbon gate from the sacrificial carbon sidewall spacers. Various embodiments replace the carbon sacrificial gate with aluminum (Al), tungsten (W), molybdenum (Mo), gold (Au), silver (Ag), gold alloy, silver alloy, copper (Cu), platinum (Pt), rhenium (Re), ruthenium (Ru), rhodium (Rh), nickel (Ni), osmium (Os), palladium (Pd), iridium (Ir), cobalt (Co), germanium (Ge), or metallic nitrides such as WN, TiN or TaN covered by metals. The high-k gate dielectric formed at 202 may be one of a number of high-k gate dielectrics. Various high-k dielectric embodiments are identified below.

High-k Dielectric Gate Insulator

As provided in the above embodiments, the sacrificial carbon gate 103 is formed on high-k gate dielectric 110. Various embodiments use the specific high-k dielectrics provided below. Some specific process examples are provided below for the identified high-k dielectric. These process examples are not intended to be limited to exclude the identified device structures if the structures are formed using other processes. According to various embodiments, a high-k dielectric can be fabricated using atomic layer deposition (ALD) processes, evaporated deposition processes, and sputtered deposition processes. Additionally, metal can be oxidized to form a high-k dielectric, and the high-k dielectric can be formed as nanolaminates of dielectric material.

Specific chemical formulas are referenced below with respect to various high-k dielectric structures. However, the dielectric structure can include stoichiometric structures, non-stoichiometric structures, and combinations of stoichiometric and non-stoichiometric structures.

AlO_(X)

Various embodiments use an aluminum oxide (AlO_(X)) formed by ALD as a high-k dielectric. For example, a pulse of an oxidant can be provided, followed by a purge or evacuation of the oxidant, followed by a pulse of a precursor containing aluminum, followed by a purge or evacuation of the aluminum-containing precursor. The aluminum precursor can include a variety of precursors, such as trimethylaluminum (TMA), trisobutylaluminum (TIBA), dimethylaluminum hydride (DMAH), AlC₃, and other halogenated precursors and organometallic precursors. Oxidants can include a water-argon mixture formed by bubbling an argon carrier through a water reservoir, H₂O₂, O₂, O₃, and N₂O. The ALD aluminum oxides are not limited to specific aluminum precursors or oxidants. Additional information regarding aluminum oxides formed by ALD can be found in US Patent Application Publication 2003/0207032-A1, entitled “Methods, Systems, and Apparatus for Atomic-Layer Deposition of Aluminum Oxides in Integrated Circuits,” which is herein incorporated by reference.

LaAlO₃

Various embodiments use a lanthanum aluminum oxide (LaAlO₃) formed by ALD as a high-k dielectric. For example, a LaAlO₃ gate dielectric can be formed using atomic layer deposition by employing a lanthanum sequence and an aluminum sequence, where the lanthanum sequence uses La(thd)₃ (thd=2,2,6,6-tetramethyl-3,5-heptanedione) and ozone, and the aluminum sequence uses either trimethylaluminum, Al(CH₃)₃, or DMEAA, an adduct of alane (AlH₃) and dimethylethylamine [N(CH₃)₂(C₂H₅)], with distilled water vapor.

A dielectric film containing LaAlO₃, Al₂O₃, and La₂O₃ will have a dielectric constant ranging from the dielectric constant of Al₂O₃, 9, to the dielectric constant of La₂O₃, 30. By controlling the number of cycles of the lanthanum sequence and the number of cycles of the aluminum sequence, the amount of lanthanum and aluminum deposited on the surface region of a substrate can be controlled. Thus, a dielectric film formed by ALD using a lanthanum sequence and an aluminum sequence can be formed with a composition containing selected or predetermined percentages of LaAlO₃, Al₂O₃, and La₂O₃, in which case the effective dielectric constant of the film will be selected or predetermined in the range from 9 to 30. A dielectric film containing almost entirely LaAlO₃ will have a dielectric constant in the range of about 21 to about 25. The resulting dielectric containing LaAlO₃ should be amorphous if an aluminum sequence is used subsequent to a lanthanum sequence.

In addition to separately controlling the number of cycles of the lanthanum sequence and the aluminum sequence in the ALD process, a dielectric film containing LaAlO₃ can be engineered with selected characteristics by also controlling precursor materials for each sequence, processing temperatures and pressures for each sequence, individual precursor pulsing times, and heat treatment at the end of the process, at the end of each cycle, and at the end of each sequence. The heat treatment may include in situ annealing in various atmospheres including argon, nitrogen, and oxygen. A range of equivalent oxide thickness is associated with the capability to provide a composition having a dielectric constant in the range from about 9 to about 30, and the capability to attain physical film thickness in the range from about 0.5 to about 50 nm and above.

Additional information regarding LaAlO₃ dielectric films can be found in US Patent Application Publication 2003/0207540-A1, entitled “Atomic Layer-Deposited LaAlO₃ Films For Gate Dielectrics,” which is herein incorporated by reference.

HfAlO

Various embodiments use a hafnium aluminum oxide (HfAlO₃) formed by ALD as a high-k dielectric. For example, an HfAlO₃ gate dielectric can be formed using atomic layer deposition by employing a hafnium sequence and an aluminum sequence, where the hafnium sequence uses HfCl₄ and water vapor, and the aluminum sequence uses either trimethylaluminum, Al(CH₃)₃, or DMEAA, an adduct of alane (AlH₃) and dimethylethylamine [N(CH₃)₂(C₂H₅)], with distilled water vapor.

A dielectric film containing HfAlO₃, Al₂O₃, and HfO₂ has a dielectric constant ranging from the dielectric constant of Al₂O₃, 9, to the dielectric constant of HfO₂, 25. By controlling the number of cycles of the hafnium sequence and the number of cycles of the aluminum sequence, the amount of hafnium and aluminum deposited on the surface region of a substrate can be controlled. Thus, a dielectric film formed by ALD using a hafnium sequence and an aluminum sequence can be formed with a composition containing selected or predetermined percentages of HfAlO₃, Al₂O₃, and HfO₂, in which case the effective dielectric constant of the film will be selected or predetermined in the range from 9 to 25. Furthermore, by using an aluminum sequence subsequent to a hafnium sequence, the resulting dielectric containing HfAlO₃ should be amorphous.

In addition to separately controlling the number of cycles of the hafnium sequence and the aluminum sequence in the ALD process, a dielectric film containing HfAlO₃ can be engineered with selected characteristics by also controlling precursor materials for each sequence, processing temperatures and pressures for each sequence, individual precursor pulsing times, and heat treatment at the end of the process, at the end of each cycle, and at the end of each sequence. The heat treatment may include in situ annealing in various atmospheres including argon and nitrogen.

A range of equivalent oxide thickness, t_(eq) is associated with the capability to provide a composition having a dielectric constant in the range from about 9 to about 25, and the capability to attain physical film thickness in the range of from about 2 to about 3 nm and above.

Additional information regarding HfAlO₃ dielectric films can be found in US Patent Application Publication 2003/0227033-A1, entitled “Atomic Layer-Deposited HfAlO₃ Films For Gate Dielectrics,” which is herein incorporated by reference.

Pr₂O₃-Based La-Oxide

Various embodiments use a Pr₂O₃-based La-Oxide dielectric as a high-k dielectric. For example, a Pr₂O₃-based La-Oxide gate dielectric can be formed by electron beam evaporation as a nanolaminate of Pr₂O₃ and a lanthanide oxide selected from the group consisting of Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃.

According to one embodiment, an electron gun generates an electron beam that hits a target that contains a ceramic Pr₆O₁₁ source, which is evaporated due to the impact of the electron beam. The evaporated material is then distributed throughout a chamber, and a dielectric layer of Pr₂O₃ is grown, forming a film on the surface of the structure that it contacts. The resultant Pr₂O₃ layer includes a thin amorphous interfacial layer of about 0.5 nm thickness separating a crystalline layer of Pr₂O₃ from the substrate on which it is grown. This thin amorphous layer is beneficial in reducing the number of interface charges and eliminating any grain boundary paths for conductance from the substrate. Other source materials can be used for forming the Pr₂O₃ layer, as are known to those skilled in the art.

Subsequent to the formation of the Pr₂O₃ layer, another lanthanide oxide is deposited on the film, converting the film from a Pr₂O₃ layer to a nanolaminate of Pr₂O₃ and the other lanthanide oxide. In various embodiments, the other lanthanide oxide is selected from the group consisting of Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃. Depending on the lanthanide oxide selected to form the nanolaminate, a corresponding source material is used in the target for electron beam evaporation. The source material for the particular lanthanide oxide is chosen from commercial materials for forming the lanthanide oxide by electron beam evaporation, as is known by those skilled in the art.

In one embodiment, alternating layers of Pr₂O₃ and another selected lanthanide oxide are formed by controlled electron beam evaporation providing layers of material of predetermined thickness. This control allows the engineering of a dielectric with a predetermined thickness and composition. Through evaluation of different lanthanide oxides at various thicknesses and number of layers, a dielectric layer with a predetermined t_(eq) in a narrow range of values can be grown. Alternatively, after forming a Pr₂O₃ layer and a layer of another lanthanide oxide, additional layers of additional lanthanide oxides can be formed. Each layer of an additional lanthanide oxide selected from a group consisting of Pr₂O₃, Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃. Consequently, a dielectric layer can be engineered with electrical characteristics suited for a given application. These electrical characteristics include t_(eq) and leakage current. A t_(eq) of less than 20 Å can be obtained, typically with sizes of about 14 Å to 8.5 Å.

In an embodiment, nanolaminates of lanthanide oxides are formed by electron beam evaporation. The lanthanide oxides used in these nanolaminates are chosen from the group consisting of Pr₂O₃, Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃. The structure of the nanolaminates can be varied with any one of the group used as the initial layer formed on a substrate. Typically, the substrate is silicon based, since these lanthanide oxides are thermodynamically stable with respect to formation on a silicon surface. In an alternate embodiment, lanthanide oxide nanolaminates are formed by atomic layer deposition.

A Pr₂O₃ film formed on silicon has a dielectric constant of about 31 when formed with little or no interfacial layer between the Pr₂O₃ film and the substrate. The dielectric constants for the other lanthanide oxides are also in the range of 25–30. As a result, a dielectric layer grown by forming a nanolaminate of lanthanide oxides has a dielectric constant in the range of about 25 to about 31. However, with an interfacial layer formed between the surface of the substrate and the first lanthanide oxide, the t_(eq) of the dielectric layer is the t_(eq) of the interfacial layer in parallel with the lanthanide oxide nanolaminate. Thus, the dielectric layer formed having an interfacial layer between the substrate on which it is grown and a lanthanide oxide nanolaminate can have an effective dielectric constant considerably less than a dielectric constant associated with a nanolaminate of lanthanide oxides. This is dependent upon the dielectric constant of the interfacial material being considerably less than the dielectric constant of the lanthanide oxides used to form the nanolaminate.

A Pr₂O₃ layer can be formed on a silicon based substrate having a dielectric constant of about 31 with an interfacial layer of about 0.5 nm (5 Å). In another embodiment, for an interfacial layer of about 10.7 Å, an effective dielectric constant for a thin layer of Pr₂O₃ on silicon is about 15. Similar effective dielectric constants are associated with thin layers of Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃ oxides on silicon. For example, a thin layer of Nd₂O₃ has an effective dielectric constant of about 12.9 with an interfacial layer of about 8.2 Å, a thin layer of Sm₂O₃ has an effective dielectric constant of about 11.4 with an interfacial layer of about 5.5 Å, a thin layer of Gd₂O₃ has an effective dielectric constant of about 13.9 with an interfacial layer of about 10 Å, and a thin layer of Dy₂O₃ has an effective dielectric constant of about 14.3 with an interfacial layer of about 12 Å. Lanthanide oxides grown on silicon with these reduced effective dielectric constants and corresponding interfacial layers can be attained with a t_(eq) equal to about 13 Å for Pr₂O₃, about 12.4 Å for Nd₂O₃, about 12.2 Å for Sm₂O₃, about 13 Å for Gd₂O₃, and about 13.3 Å for Dy₂O₃. Consequently, nanolaminates of these lanthanide oxides can be formed with an effective dielectric constant in the range of 111 to 15 and a t_(eq) in the range of about 12 Å to about 14 Å.

The formation of the interfacial layer is one factor in determining how thin a layer can be grown. An interfacial layer can be SiO₂ for many processes of forming a non-SiO₂ dielectric on a silicon substrate. However, advantageously, in an embodiment forming a lanthanide oxide nanolaminate with an initial layer of Pr₂O₃, a thin amorphous interfacial layer is formed that is not a SiO₂ layer. Typically, this interfacial layer is either an amorphous layer primarily of Pr₂O₃ formed between the silicon substrate and a crystalline form of Pr₂O₃, or a layer of Pr—Si—O silicate. The dielectric constant for Pr—Si—O silicate is significantly greater than SiO₂, but not as high as Pr₂O₃.

Another factor setting a lower limit for the scaling of a dielectric layer is the number of monolayers of the dielectric structure necessary to develop a full band gap such that good insulation is maintained between an underlying silicon layer and an overlying conductive layer on the dielectric layer or film. This requirement is necessary to avoid possible short circuit effects between the underlying silicon layer and the overlying conductive layer used. In one embodiment, for a 0.5 nm interfacial layer and several monolayers of lanthanide grown, an expected lower limit for the physical thickness of a dielectric layer grown by forming a lanthanide oxide nanolaminate is anticipated to be in about the 2–4 nm range. Consequently, typical dielectric layers or films can be grown by forming lanthanide oxide nanolaminates having physical thicknesses in the range of 4 to 10 nm. The number of layers used, the thickness of each layer, and the lanthanide oxide used for each layer can be engineered to provide the desired electrical characteristics. The use of Pr₂O₃ as the initial layer is expected to provide excellent overall results with respect to reliability, current leakage, and ultra-thin t_(eq).

Some embodiments include forming lanthanide oxide nanolaminates by electron beam evaporation with target material to form Pr₂O₃, forming lanthanide oxide nanolaminates by atomic layer deposition, and electron beam evaporation forming lanthanide oxide nanolaminates with initial layers of a lanthanide oxide other than Pr₂O₃. The physical thicknesses can range from about 2 nm to about 10 nm, with typical thickness ranging from about 4 nm to about 10 nm. Such layers have an effective dielectric constant ranging from 11 to 31, where a layer with a typical interfacial layer has an effective dielectric constant in the range of 11 to 16, and a layer with a significantly thin interfacial layer can attain an effective dielectric constant in the range of 25 to 31. Consequently, the equivalent oxide thickness of a dielectric layer formed as a lanthanide oxide nanolaminate can be engineered over a significant range. Various embodiments provide a typical t_(eq) of about 14 Å. With careful preparation and engineering of the lanthanide oxide nanolaminate limiting the size of interfacial regions, a t_(eq) down to 2.5 Å or lower is anticipated.

Additional information regarding Pr₂O₃-based La-Oxide dielectric films can be found in US Patent Application Publication 2003/0228747-A1, entitled “Pr₂O₃-based La-Oxide Gate Dielectrics,” which is herein incorporated by reference.

Lanthanide Doped TiO_(x)

A lanthanide doped TiO_(x) dielectric layer can be formed by depositing titanium and oxygen onto a substrate surface by atomic layer deposition and depositing a lanthanide dopant by atomic layer deposition onto the substrate surface containing the deposited titanium and oxygen. The dopant can be selected from a group consisting of Nd, Tb, and Dy.

In one embodiment, a method of forming a dielectric film includes depositing titanium and oxygen onto a substrate surface by atomic layer deposition and depositing a lanthanide dopant by atomic layer deposition onto the substrate surface containing the deposited titanium and oxygen. In one embodiment, the titanium sequence and the lanthanide dopant sequence include using precursors that form oxides of the titanium and the lanthanide dopant. For example, precursor TiI₄ with H₂O₂ as its reactant precursor in an ALD process can form TiO_(x), and precursor La(thd)₃ (thd=2,2,6,6-tetramethyl-3,5-heptanedione) with ozone as its reactant precursor in an ALD process can form La₂O₃.

Depositing the lanthanide dopant includes regulating the deposition of the lanthanide dopant relative to the titanium and oxygen deposited on the substrate surface to form a dielectric layer containing TiO_(x) doped with a predetermined percentage of the lanthanide. In a further embodiment, depositing a lanthanide dopant includes depositing a lanthanide selected from a group consisting of Nd, Tb, and Dy.

The lanthanide dopant can be included in the TiO_(x) film using different embodiments for atomic layer deposition. In one embodiment, a lanthanide can be doped in the TiO_(x) film by pulsing a lanthanide dopant sequence in place of a titanium sequence. The lanthanide dopant level is then controlled by regulating the number of cycles of the lanthanide dopant sequence with respect to the number of cycles of the titanium sequence. In another embodiment, a lanthanide can be doped in the TiO_(x) film by pulsing a lanthanide dopant precursor substantially simultaneously with a titanium precursor. The titanium/lanthanide dopant sequence includes a precursor for oxidizing the titanium/lanthanide dopant at the substrate surface. The lanthanide dopant level is then controlled by regulating the mixture of the titanium-containing precursor and the lanthanide-containing precursor.

Dielectric films of lanthanide doped TiO_(x) formed by atomic layer deposition can provide not only ultra thin t_(eq) films, but also films with relatively low leakage current. In addition to using ALD to provide precisely engineered film thicknesses, attainment of relatively low leakage current is engineered by doping with lanthanides selected from a group consisting of Nd, Tb, and Dy. Though a layer of undoped TiO_(x) can be amorphous, which assists in the reduction of leakage current, doping with these lanthanides yields a doped amorphous TiO_(x) with enhanced leakage current characteristics. Leakage currents on the order of 10⁻⁷ A/cm² or smaller in TiO_(x) layers doped with Nd, Tb, or Dy can be attained, which are orders of magnitude smaller than for undoped TiO_(x). Further, the breakdown electric fields are several factors larger for layers of TiO_(x) doped with Nd, Tb, or Dy than for layers of undoped TiO_(x).

The doping of the TiO_(x) layer with a lanthanide occurs as a substitution of a lanthanide atom for a Ti atom. The resultant doped TiO_(x) layer is a layer of amorphous Ti_(1-y)L_(y)O_(x), where L is a lanthanide. Controlling the ALD cycles of the titanium sequence and the lanthanide dopant sequence allows a Ti_(1-y)L_(y)O_(x), or lanthanide doped TiO_(x), dielectric layer to be formed where the lanthanide, L, can range from about 5% to about 40% of the dielectric layer formed. Such TiO_(x) layers doped with Nd, Tb, or Dy formed by ALD can provide the reduced leakage current and increased breakdown mentioned above.

Additional information regarding lanthanide doped TiO_(x) dielectric films can be found in US Patent Application Publication 2004/0043541-A1, entitled “Atomic Layer Deposited Lanthanide Doped TiO_(x) Dielectric Films,” which is herein incorporated by reference.

HfSiON

A HfSiON dielectric can be formed by atomic layer deposition. A HfSiON layer thickness is controlled by repeating for a number of cycles a sequence including pulsing a hafnium-containing precursor into a reaction chamber, pulsing an oxygen-containing precursor into the reaction chamber, pulsing a silicon-containing precursor into the reaction chamber, and pulsing a nitrogen-containing precursor until a desired thickness is formed.

The hafnium-containing precursor includes a HfCl₄ precursor in some embodiments, and a HfI₄ precursor in other embodiments. According to some embodiments, the oxygen-containing precursor includes water vapor or a vapor solution of H₂O—H₂O₂ in the reaction chamber. According to some embodiments, the silicon-containing precursor includes a SiCl₄ precursor. A nitrogen-containing precursor includes a NH₃ precursor in some embodiments. NH₃ annealing at about 550° C. can also be performed.

Additional information regarding HfSiON dielectric films can be found in US Patent Application Publication 2004/0043569-A1, entitled “Atomic Layer Deposited HfSiON Dielectric Films,” which is herein incorporated by reference.

Zr—Sn—Ti—O

A Zr—Sn—Ti—O dielectric layer can be formed by depositing titanium and oxygen onto a substrate surface by atomic layer deposition, depositing zirconium and oxygen onto a substrate surface by atomic layer deposition, and depositing tin and oxygen onto a substrate surface by atomic layer deposition. Metal chloride precursors can be pulsed for each metal in the Zr—Sn—Ti—O. In some embodiments, the dielectric film is formed by depositing TiO₂ onto a surface by atomic layer deposition, depositing zirconium and oxygen onto the surface by atomic layer deposition, and depositing tin and oxygen onto the surface by atomic layer deposition. The TiO₂ deposition can include pulsing a TiCl₄ precursor. The zirconium and oxygen deposition can include pulsing a ZrCl₄ precursor. The tin and oxygen deposition can include pulsing a SnCl₄ precursor. In various embodiments, the formation of the dielectric film is controlled such that the dielectric film has a composition substantially of Zr_(y)Sn_(x)Ti_(1-x-y)O₄ with 0.3<y<0.7 and 0<x<0.2.

In some embodiments, the dielectric film is formed by depositing TiO₂ onto a surface by atomic layer deposition using a TiI₄ precursor; depositing zirconium and oxygen by atomic layer deposition using a zirconium halide precursor following forming TiO₂; and depositing tin and oxygen by atomic layer deposition using a tin halide precursor following depositing zirconium and oxygen. The zirconium and oxygen deposition can include pulsing a ZrI₄ precursor. The tin and oxygen deposition can include pulsing a SnI₄ precursor. In various embodiments, the formation of the dielectric film is controlled such that the dielectric film has a composition substantially of Zr_(y)Sn_(x)Ti_(1-x-y)O₄ with 0.3<y<0.7 and 0<x<0.2. In various embodiments, the formation of the dielectric film is controlled such that the dielectric film has a composition substantially of Zr_(0.2)Sn_(0.2)Ti_(0.6)O₂.

Additional information regarding Zr—Sn—Ti—O dielectric films can be found in US Patent Application Publication 2004/0110391-A1, entitled “Atomic Layer Deposited Zr—Sn—Ti—O Films,” and US Patent Application Publication 2004/0110348-A1, entitled “Atomic Layer Deposited Zr—Sn—Ti—O Films using TiI₄,” which are herein incorporated by reference.

Metal Oxynitride

The high-k dielectric film can be formed as a metal oxynitride, formed by atomic layer deposition of a plurality of reacted monolayers. The monolayers comprise at least one each of a metal, an oxide and a nitride. According to various embodiments, the metal oxynitride layer is formed from zirconium oxynitride, hafnium oxynitride, tantalum oxynitride, or mixtures thereof.

According to various process embodiments, a plurality of gaseous precursors can be separately introduced to a surface of the semiconductor substrate. The gaseous precursors comprise a metal gaseous precursor and at least two nonmetallic gaseous precursors. A first gaseous precursor of the plurality of gaseous precursors is purged or evacuated from the surface of the semiconductor substrate before a second gaseous precursor of the plurality of gaseous precursors is introduced to the surface of the semiconductor substrate. The metal gaseous precursor can include zirconium tetrachloride, zirconium tetraiodide, hafnium tetrachloride, hafnium tetraiodide, or a halogenated tantalum. An oxygen-containing gaseous precursor and a nitrogen-containing gaseous precursor are separately introduced to the surface of the semiconductor substrate. For example, water or hydrogen peroxide can be used as the oxygen-containing gaseous precursor and at least one of ammonia, tert-butylamine, allylamine, and 1,1-dimethylhydrazine can be used as the nitrogen-containing gaseous precursor. Thus, monolayers of metal, oxide, and nitride are formed, and the metal, oxide, and nitride monolayers are reacted to form the metal oxynitride layer.

Additional information regarding metal oxynitride dielectric layers can be found in US Patent Application Publication 2004/0144980-A1, entitled “Atomic Layer Deposition of Metal Oxynitride Layers as Gate Dielectrics and Semiconductor Device Structures Utilizing Metal Oxynitride Layers,” which is herein incorporated by reference.

HfO₂/Hf

The high-k dielectric film can be HfO₂/Hf, which can be formed by depositing a hafnium metal layer on a substrate surface by atomic layer deposition and depositing a hafnium oxide layer on the hafnium metal layer by atomic layer deposition to form a hafnium oxide dielectric layer substantially free of silicon oxide. In general, a layer of a metal is formed on a substrate by atomic layer deposition, and an oxide of the metal is formed on the metal by atomic layer deposition.

A hafnium nitrate precursor, such as an anhydrous hafnium nitrate precursor, can be used to form the layer of hafnium. A layer of hafnium oxide can be formed using an anhydrous hafnium nitrate precursor and a water vapor precursor. The substrate may be maintained at about 180° C. during the formation of the layer of hafnium and the formation of the layer of hafnium oxide.

Additional information regarding metal oxide/metal dielectric films, such as HfO₂/Hf, can be found in US Patent Application Publication 2004/0175882-A1, entitled “Atomic Layer Deposited Dielectric Layers,” which is herein incorporated by reference.

ZrAl_(x)O_(y)

The high-k dielectric film can be ZrAl_(x)O_(y), which can be formed by ALD by pulsing a zirconium-containing precursor onto a substrate, pulsing a first oxygen-containing precursor, pulsing an aluminum-containing precursor, and pulsing a second oxygen-containing precursor to form ZrAl_(x)O_(y). A precursor can be used that includes both zirconium and oxygen to provide the zirconium and oxygen in one pulsing process, and a precursor can be used that contains both aluminum and oxygen to provide the aluminum and oxygen in one pulse. In various embodiments, the dielectric layer contains Zr₄AlO₉. An interfacial layer of silicon oxide or silicon between the substrate and the ZrAl_(x)O_(y) dielectric can be less than about 1 nm. The zirconium-containing precursor can be selected from ZrCl₄ and ZrI₄ precursors. The aluminum-containing precursor can be selected from trimethylaluminum and DMEAA. Oxygen-containing precursors can be selected from H₂O, H₂O₂, and a H₂O—H₂O₂ mixture.

Additional information regarding ZrAl_(x)O_(y) dielectric layers can be found in US Patent Application Publication 2005/0054165-A1, entitled “Atomic Layer Deposited ZrAl_(x)O_(y) Dielectric Layers,” which is herein incorporated by reference.

ZrTiO₄

The high-k dielectric film can be ZrTiO₄, which can be formed by ALD by pulsing a titanium-containing precursor onto a substrate, and pulsing a zirconium-containing precursor to form an oxide containing Zr and Ti. The pulsing of the titanium-containing precursor and the pulsing of the zirconium-containing precursor is controlled to provide a dielectric layer with a predetermined zirconium to titanium ratio. In various embodiments, the ZrTiO₄ film is formed with a Zr/Ti ratio of about 0.4/0.6. A zirconium-containing precursor used to form the oxide containing Zr and Ti can include zirconium tertiary-butoxide. The titanium-containing precursor can be selected from TiCl₄, TiI₄, Ti(OCH(CH₃)₂)₄, and Ti(OC₂H₅)₄. The first pulsing of the titanium-containing precursor can be performed before pulsing the zirconium tertiary-butoxide precursor.

Reactant precursors that can be used after pulsing the titanium-containing precursor and pulsing the zirconium tertiary-butoxide precursor can be selected from H₂O, H₂O₂, alcohol (ROH), N₂O, O₃, and O₂. The substrate can be kept at a temperature ranging from about 200° C. to about 400° C. A silicon nitride layer can be formed between the substrate and the film containing ZrTiO₄. The ALD-formed film can be a nanolaminate of ZrO₂ and TiO₂.

Additional information regarding ZrTiO₄ dielectric layers can be found in US Patent Application Publication 2004/0214399-A1, entitled “Atomic Layer Deposited ZrTiO₄ Films,” which is herein incorporated by reference.

Zr-Doped Ta Oxide

The high-k dielectric film can be a zirconium-doped tantalum oxide dielectric layer, such as can be formed by depositing tantalum by atomic layer deposition onto a substrate surface and depositing a zirconium dopant by atomic layer deposition onto the substrate surface. The formation of the zirconium-doped tantalum oxide can include pulsing a tantalum-containing precursor to deposit tantalum onto a substrate surface, pulsing an oxygen-containing precursor to deposit oxygen onto the substrate surface, repeating for a number of cycles the pulsing of the tantalum-containing precursor and the pulsing of the oxygen-containing precursor, and substituting a zirconium cycle for one or more cycles of the pulsing of the tantalum-containing precursor. The zirconium cycle includes pulsing a zirconium-containing precursor to deposit zirconium onto the substrate surface. A reactant precursor is selected to produce an oxidizing reaction for the zirconium at the substrate surface. According to various embodiments, a tantalum-containing precursor includes Ta(OC₂H₅)₅, and a zirconium-containing precursor includes ZrI₄.

Additional information regarding zirconium-doped tantalum oxide dielectric layers can be found in U.S. patent application Ser. No. 10/909,959, filed Aug. 2, 2004, entitled “Atomic Layer Deposition of Zirconium-Doped Tantalum Oxide Films,” which is herein incorporated by reference.

HfO₂—Si₃N₄ on SiO₂

The high-k dielectric layer can be formed by depositing HfO₂-Silicon-Nitride by atomic layer deposition. The HfO₂-Silicon-Nitirde is formed on SiO₂. The silicon nitride can be formed using SiCl₄ and NH₃ gases, and HfO₂ can be formed by ALD using hafnium tetraiodide and oxygen as precursors. Anhydrous Hf(NO₃)₄ and H₂O vapor may also be used.

Ru Gate and La-Oxide

Various embodiments use a lanthanide oxide high-k dielectric with a ruthenium or ruthenium oxide gate. In various embodiments, the lanthanide oxide dielectric layer is formed by depositing lanthanum by atomic layer deposition onto a substrate surface using a trisethylcyclopentadionatolanthanum precursor or a trisdipyvaloylmethanatolanthanum precursor. A ruthenium gate on a lanthanide oxide dielectric layer provides a gate structure that effectively prevents a reaction between the gate and the lanthanide oxide dielectric layer.

Additional information regarding ruthenium on lanthanide oxide can be found in U.S. patent application Ser. No. 10/926,812, filed Aug. 26, 2004, entitled “Ruthenium Gate For a Lanthanide Oxide Dielectric Layer,” which is herein incorporated by reference.

TiAlO_(x)

The high-k dielectric film can be provided by a titanium aluminum oxide film, which can be formed by depositing titanium and/or aluminum by atomic layer deposition onto a substrate surface. The deposited titanium and/or aluminum is annealed using atomic oxygen. After annealing, a layer of titanium aluminum oxide is formed on the annealed layer to form a contiguous layer of titanium aluminum oxide.

Forming the dielectric includes forming an insulating metal oxide, which includes forming a first layer of at least one of a first metal and a second metal by atomic layer deposition, annealing the first layer using oxygen, and forming, after annealing the first layer, a second layer of an insulating metal oxide of the first metal and the second metal onto the first layer by atomic layer deposition to form a contiguous layer. The first layer can include a layer of the first metal and the second metal. The first layer can have a thickness of about one monolayer or at most substantially two monolayers.

According to various embodiments, a first layer of titanium aluminum oxide is formed by atomic layer deposition, and the first layer is annealed using atomic oxygen. A second layer of titanium aluminum oxide is formed onto the first layer by atomic layer deposition, after annealing the first layer, to form a contiguous layer. The first layer of titanium aluminum oxide can be formed using TiI₄ or trimethylaluminum as a precursor, and the second layer of titanium aluminum oxide can be formed using TiCl₄ as a precursor. The titanium oxide and the titanium aluminum oxide film can be formed as a nanolaminate.

Additional information regarding titanium aluminum oxide films can be found in U.S. patent application Ser. No. 10/931,533, filed Aug. 31, 2004, entitled “Atomic Layer Deposited Titanium Aluminum Oxide Films,” which is herein incorporated by reference.

LaAlO_(X)

The high-k dielectric film can be provided by a lanthanum aluminum oxide dielectric layer, which can be formed by depositing aluminum and lanthanum by atomic layer deposition onto a substrate surface in which precursors to deposit the lanthanum include a trisethylcyclopentadionatolanthanum precursor and/or a trisdipyvaloylmethanatolanthanum precursor, and a metal (e.g. Al) containing precursor is also used. The lanthanum aluminum oxide can be formed as a compound of lanthanum oxide and aluminum oxide. The dielectric layer can include LaAlO₃.

Additional information regarding titanium aluminum oxide films can be found in U.S. patent application Ser. No. 10/930,167, filed Aug. 31, 2004, entitled “Atomic Layer Deposited Lanthanum Aluminum Oxide Dielectric Layer,” which is herein incorporated by reference.

La₂Hf₂O₇

The high-k dielectric can be provided as a lanthanum hafnium oxide layer, which can be formed by depositing hafnium and lanthanum by atomic layer deposition onto a substrate surface. The process includes introducing a lanthanum-containing precursor to a substrate, and introducing a hafnium-containing precursor to the substrate. Embodiments include methods and apparatus in which precursors to deposit the lanthanum include a trisethylcyclopentadionatolanthanum (La(EtCp)₃) precursor, a tris (2,2,6,6-tetramethyl-3,5-heptanedionato) lanthanum (III) precursor, a trisdipyvaloylmethanatolanthanum precursor, or a tris (2,2,6,6-tetramethyl-3,5-heptanedionato)lanthanum (III) tetraglyme adduct precursor.

Additional information regarding titanium aluminum oxide films can be found in U.S. patent application Ser. No. 11/010,529, filed Dec. 13, 2004, entitled “Atomic Layer Deposited Lanthanum Hafnium Oxide Dielectrics,” which is herein incorporated by reference.

HfTaO

The high-k dielectric can be provided as a hafnium tantalum oxide film, which can be formed by depositing hafnium and tantalum by atomic layer deposition onto a substrate surface. A tantalum-containing precursor can include a tantalum ethoxide precursor, and a hafnium-containing precursor can include a hafnium nitrate precursor.

Additional information regarding titanium aluminum oxide films can be found in U.S. patent application Ser. No. 11/029,757, filed Jan. 5, 2005, entitled “Atomic Layer Deposited Hafnium Tantalum Oxide Dielectrics,” which is herein incorporated by reference.

Hafnium Titanium Oxide

The high-k dielectric can be provided as hafnium titanium oxide, such as HfTiO₄, formed by ALD using precursors substantially free of chlorine and carbon. Precursors capable of being used include a titanium halide precursor such as a titanium iodine precursor, a titanium nitride precursor, a titanium isopropoxide precursor, and a hafnium halide precursor such as a hafnium chloride precursor.

Amorphous Lanthanide Doped TiO_(X)

The high-k dielectric can be provided as an ALD-formed amorphous dielectric layer of titanium oxide (TiO_(X)) doped with lanthanide elements, such as samarium, europium, gadolinium, holmium, erbium and thulium. The dielectric structure is formed by depositing titanium oxide by atomic layer deposition onto a substrate surface using precursor chemicals, followed by depositing a layer of a lanthanide dopant, and repeating to form a sequentially deposited interleaved structure. The leakage current of the dielectric layer is reduced when the percentage of the lanthanide element doping is optimized. The amorphous dielectric layer is formed on a substrate by atomic layer deposition at a predetermined temperature, such as within a range of approximately 100° C. to 250° C. The amorphous dielectric layer can be comprised of a plurality of individual titanium oxide layers, with at least one lanthanide layer interleaved between each individual one of the titanium oxide layers. The dielectric layer can have a titanium to lanthanide ratio selected to obtain a dielectric constant value of from 50 to 100, and can be selected with a titanium to lanthanide ratio selected to obtain a leakage current of less than 10⁻⁸ A/cm² and a breakdown voltage of greater than 2.0 MV/cm.

Additional information regarding titanium aluminum oxide films can be found in U.S. patent application Ser. No. 11/092,072, filed Mar. 29, 2005, entitled “ALD of Amorphous Lanthanide Doped TiO_(X) Films,” which is herein incorporated by reference.

Ti Gate Dielectric

The high-k dielectric can be provided as a Ti gate dielectric, which may be formed by providing a substrate assembly in a vacuum chamber, and forming a gate dielectric on the surface, including forming a metal oxide on at least a portion of the surface of the substrate assembly by electron beam evaporation, and generating an ion beam using an inert gas to provide inert gas ions for contacting the metal oxide during formation thereof. An environment including oxygen (e.g. ozone) can be provided in the vacuum chamber to form the metal oxide in the oxygen environment. The metal oxide can be selected from the group consisting of TiO₂, Y₂O₃, Al₂O₃, ZrO₂, HfO₂, Y₂O₃—ZrO₂, ZrSiO₄, LaAlO₃, and MgAl₂O₄.

Additional information regarding titanium aluminum oxide films can be found in U.S. Pat. No. 6,495,436, entitled “Formation Of Metal Oxide Gate Dielectric,” which is herein incorporated by reference.

TiO₂

The high-k dielectric can be provided as a TiO₂ dielectric, which can be physically vapor formed as a high purity metal layer over the semiconductor substrate. After forming such a layer, the high purity metal layer can be oxidized employing atomic oxygen generated in a high density plasma environment to form the dielectric material. The physically vapor formed high purity metal layer can have at least about 99.9% purity over the semiconductor substrate. The physical vapor formation can include electron beam evaporation. Prior to the electron beam evaporation, the vacuum chamber can be evacuated to a base pressure of about 1×10⁻⁷ Torr or lower, and a low-energy ion-bombardment source is directed towards the semiconductor substrate during the electron beam evaporation. A low-energy argon ion-bombardment can be directed towards the semiconductor substrate during the electron beam evaporation. The high purity metal layer can include two or more high purity metals, such as a metal-silicon alloy. The high purity metal can be selected from titanium, yttrium, zirconium, hafnium and various mixtures thereof.

Additional information regarding TiO₂ films can be found in U.S. Pat. No. 6,534,420, entitled “Methods For Forming Dielectric Materials and Methods for Forming Semiconductor Devices,” which is herein incorporated by reference.

Amorphous HfO₂

The high-k dielectric can include hafnium oxide, which can be formed by forming a thin hafnium (Hf) film by thermal evaporation at a low substrate temperature, and radically oxidizing the thin hafnium film using a krypton/oxygen (Kr/O₂) high-density plasma to form the gate dielectric layer of hafnium oxide (HfO₂). The resulting gate dielectric layer is thermally stable in contact with silicon and is resistive to impurity diffusion at the HfO₂/silicon interface. The formation of the HfO₂ eliminates the need for a diffusion barrier layer, allows thickness uniformity of the field oxide on the isolation regions, and preserves the atomically smooth surface of the silicon substrate. The hafnium layer can be formed by electron beam evaporation.

Additional information regarding HfO₂ and other amorphous high-k gate oxide films can be found in U.S. Pat. No. 6,514,828, entitled “Method of Fabricating a Highly Reliable Gate Oxide,” which is herein incorporated by reference.

CoTiO₃

The high-k dielectric can be provided by CoTiO₃, which can be formed from alloys such as cobalt-titanium. These alloys are thermodynamically stable such that the gate dielectrics formed will have minimal reactions with a silicon substrate or other structures during any later high temperature processing stages. The underlying substrate surface smoothness is preserved by using a thermal evaporation technique to deposit the layer to be oxidized. A metal alloy layer is evaporation deposited on the body region, and the metal alloy layer is oxidized to form a metal oxide layer on the body region. Cobalt and titanium can be evaporation deposited, such as by electron beam evaporation. The evaporation deposition of the metal alloy layer can be performed at a substrate temperature range of 100–150° C., and the oxidation of the metal alloy layer can be performed at a temperature of approximately 400° C. A krypton (Kr)/oxygen (O₂) mixed plasma can be used in the oxidization process.

Additional information regarding HfO₂ and other amorphous high-k gate oxide films can be found in US Patent Publication No. 2003/0119246A1, entitled “Low-Temperature Grown High Quality Ultra-Thin CoTiO₃ Gate Dielectrics,” which is herein incorporated by reference.

Oxides of Group IVB Elements (e.g. ZrO₂)

The high-k gate dielectric can be formed from elements like zirconium, such as ZrO₂, which are thermodynamically stable such that the gate dielectric will have little reaction with a silicon substrate or other structures during any later high temperature processing stages. The gate dielectric can be formed by evaporation depositing a metal layer on the body region, the metal being chosen from the group IVB elements of the periodic table, and oxidizing the metal layer to form a metal oxide layer on the body region. The metal layer can include a zirconium layer, which can be deposited by electron beam evaporation. The substrate temperature range for the deposition can be within a range of 150–400° C. The oxidation can be performed using atomic oxygen or with a krypton (Kr)/oxygen (O₂) mixed plasma, for example.

Additional information regarding ZrO₂ and other amorphous high-k gate oxide films can be found in US Patent Publication No. 2003/0045078-A1, entitled “Highly Reliable Amorphous High-K Gate Oxide ZrO₂,” which is herein incorporated by reference.

Group IIIB/Rare Earth Series (Crystalline or Amorphous Y₂O₃ and Gd₂O₃)

The high-k dielectric can be provided using elements such as yttrium and gadolinium, which are thermodynamically stable such that the resulting gate dielectrics have minimal reaction with a silicon substrate or other structures during any later high temperature processing stages. The underlying substrate surface smoothness is preserved using a thermal evaporation technique to deposit the layer to be oxidized. The gate dielectric can be formed by evaporation depositing a metal layer on the body region, where the metal is chosen from a group consisting of the group IIIB elements and the rare earth series of the periodic table, and by oxidizing the metal layer to form a metal oxide layer on the body region. The metal layer can be yttrium and can be gadolinium. Electron beam evaporation can be used. The substrate temperature for the deposition can be approximately 150–400° C. Atomic oxygen and a krypton (Kr)/oxygen (O₂) mixed plasma can be used to oxidize the metal layer, for example.

Additional information regarding gate oxides formed from elements such as yttrium and gadolinium can be found in U.S. Pat. No. 6,844,203 entitled “Gate Oxides, and Methods of Forming,” which is herein incorporated by reference.

Praseodymium Oxide

The gate dielectric can be provided by a praseodymium oxide. The Pr gate oxide is thermodynamically stable so that the oxide reacts minimally with a silicon substrate or other structures during any later high temperature processing stages. The underlying substrate surface smoothness is preserved using a thermal evaporation technique to deposit a Pr layer to be oxidized. The gate dielectric can be formed by evaporation depositing a praseodymium (Pr) layer on the body region, and oxidizing the Pr layer to form a Pr₂O₃ layer on the body region. Electron beam evaporation can be used. The substrate temperature for the deposition can be in an approximate range of 150–400° C. Atomic oxygen and a krypton (Kr)/oxygen (O₂) mixed plasma can be used to oxidize the Pr layer, for example. The Pr₂O₃ layer can be formed to have an equivalent oxide thickness of less than 2 nm.

Additional information regarding praseodymium gate oxides can be found in U.S. Pat. No. 6,900,122, entitled “Low-Temperature Grown High-Quality Ultra-Thin Praseodymium Gate Dielectrics,” which is herein incorporated by reference.

ZrO_(X)N_(Y)

The high-k dielectric can be provided by a metal oxynitride such as ZrO_(X)N_(Y). The addition of nitrogen to the microstructure of the gate dielectric promotes an amorphous phase that provides the gate dielectric with improved electrical properties. The underlying substrate surface smoothness is preserved by using a thermal evaporation technique to first deposit a metal layer. The gate dielectric can be formed by evaporation depositing a metal layer such as a zirconium layer on the body region, oxidizing the metal layer, and nitriding the metal layer. Electron beam evaporation can be used. The substrate temperature for the deposition can be in an approximate temperature range of 150–400° C. Atomic oxygen and a krypton (Kr)/oxygen (O₂) mixed plasma, for example, can be used to oxidize the metal layer. The metal layer can be annealed in NH₃ at a temperature of approximately 700° C.

Additional information regarding ZrO_(X)N_(Y) gate oxides can be found in U.S. Pat. No. 6,767,795 entitled “Highly Reliable Amorphous High-K Gate Dielectric ZrOxNy,” which is herein incorporated by reference.

LaAlO₃

The high-k dielectric can be provided by LaAlO₃. A LaAlO₃ gate dielectric can be formed by evaporating Al₂O₃ at a given rate, evaporating La₂O₃ at another rate, and controlling the two rates to provide an amorphous film containing LaAlO₃ on a transistor body region. The evaporation deposition of the LaAlO₃ film is performed using two electron guns to evaporate dry pellets of Al₂O₃ and La₂O₃. The two rates for evaporating the materials are selectively chosen to provide a dielectric film composition having a predetermined dielectric constant ranging from the dielectric constant of an Al₂O₃ film to the dielectric constant of a La₂O₃ film. Electron beam evaporation can be used. A predetermined dielectric constant can be achieved by controlling the evaporation rates.

Additional information regarding evaporated LaAlO₃ gate dielectrics can be found in U.S. Pat. No. 6,893,984, entitled “Evaporated LaAlO₃ Films for Gate Dielectrics,” which is herein incorporated by reference.

TiO_(X)

The high-k dielectric can be provided by TiO_(X). The dielectric film can be formed by ion assisted electron beam evaporation of TiO₂ and electron beam evaporation of a lanthanide selected from a group consisting of Nd, Tb, and Dy. The growth rate is controlled to provide a dielectric film having a lanthanide content ranging from about ten to about thirty percent of the dielectric film. These dielectric films containing lanthanide doped TiO_(x) are amorphous and thermodynamically stable such that the lanthanide doped TiO_(x) will have minimal reaction with a silicon substrate or other structures during processing.

The film can be formed by evaporating TiO₂ at a first rate, evaporating a lanthanide at a second rate, and controlling the first rate and the second rate to grow a dielectric film on a substrate, the dielectric film containing TiO_(x) doped with the lanthanide. The lanthanide can be selected from a group consisting of Nd, Tb, and Dy. Electron beam evaporation can be used. The rates can be controlled to selectively grow the dielectric film doped in the range from about 10% to about 30% lanthanide. The rates can be controlled so that the dielectric film has a dielectric constant ranging from about 50 to about 110.

Additional information regarding evaporated lanthanide doped TiO_(X) dielectric films can be found in U.S. Pat. No. 6,790,791 entitled “Lanthanide Doped TiO_(X) Dielectric Films,” which is herein incorporated by reference.

TiO_(X) by Kr Plasma Oxidation

The high-k dielectric can be provided by TiO_(X), which can be formed by ion assisted electron beam evaporation of Ti, electron beam evaporation of a lanthanide selected from a group consisting of Nd, Tb, and Dy, and oxidation of the evaporated Ti/lanthanide film in a Kr/oxygen plasma. The growth rate is controlled to provide a dielectric film having a lanthanide content ranging from about five to about forty percent of the dielectric film. These dielectric films containing lanthanide doped TiO_(x) are amorphous and thermodynamically stable such that the lanthanide doped TiO_(x) will have minimal reaction with a silicon substrate or other structures during processing. Electron beam evaporation can be used. The rates can be controlled to provide a lanthanide doped Ti film on the substrate for growing a dielectric film doped in the range from about 5% to about 40% lanthanide. The rates can be controlled to provide the film with a dielectric constant ranging from about 50 to about 110.

Additional information regarding evaporated lanthanide doped TiOx dielectric films can be found in U.S. Pat. No. 6,884,739 entitled “Lanthanide Doped TiOx Dielectric Films By Plasma Oxidation,” which is herein incorporated by reference.

Y—Si—O

The dielectric can be provided by Y—Si—O dielectrics formed by evaporation deposition techniques.

Oxidation of Metals

The high-k dielectric can be provided by oxidizing metal. Examples of metal oxides include PbO, Al₂O₃, Ta₂O₅, TiO₂, ZrO₂, and Nb₂O₅.

Additional information regarding oxidation of metals for high-k dielectrics can be found in US Patent Application Publication 2003/0043637-A1 entitled “Flash Memory With Low Tunnel Barrier Interpoly Insulators,” which is herein incorporated by reference.

HfO₂/La₂O₃

The high-k dielectric can be provided by an HfO₂/La₂O₃ nanolaminate structure. The dielectric can be formed by forming a first metal-containing dielectric layer over the surface of the substrate, the metal comprising an element selected from Group IVB of the periodic table, and forming a second metal-containing dielectric layer over the first metal-containing dielectric layer. For example, the first metal-containing dielectric layer can include hafnium, and the second metal-containing dielectric layer comprises lanthanum.

A layer of silicon dioxide can be formed to overlie at least one portion of the surface; and the first metal-containing dielectric layer can be formed by forming a metal layer over the layer of silicon dioxide, and combining metal of the metal layer with oxygen of the silicon dioxide layer to form a metal oxide dielectric material. The second metal-containing dielectric layer can be an element selected from Group IIIB of the periodic table.

According to various embodiments, the dielectric is formed by forming a hafnium-containing layer, forming a lanthanum-containing layer over the hafnium-containing layer, and exposing the hafnium-containing layer and the lanthanum-containing layer to an oxygen-comprising atmosphere and heating the hafnium-containing layer and the lanthanum-containing layer to a temperature effective to form a hafnium-containing dielectric layer and a lanthanum-containing dielectric layer. Physical vapor deposition can be used. The thickness of each of the hafnium-containing dielectric layer and the lanthanum-containing dielectric layer can be less than about 5 nm. The ratio of the hafnium thickness to the lanthanum thickness can be from about 1 to 3 to about 1 to 4.

Additional information regarding nanolaminates such as HfO₂/La₂O₃ as high-k dielectrics can be found in US Patent Application Publication 2002/0192974 A1 entitled “Dielectric Layer Forming Method and Devices Formed Therewith,” which is herein incorporated by reference.

La₂O₃/Hf₂O₃

The high-k dielectric can be provided by an La₂O₃/Hf₂O₃ nanolaminate. Alternate layers of hafnium oxide and lanthanum oxide over a substrate can be deposited to form a composite. The dielectric can be provided by forming one hafnium oxide monolayer, forming one lanthanum oxide monolayer, and repeating to form a plurality of single hafnium oxide monolayers interspersed among a plurality of single lanthanum oxide monolayers. Multiple hafnium oxide monolayers can be formed to create a hafnium oxide multilayer, and multiple lanthanum oxide monolayers can be formed to create a lanthanum oxide multilayer. A plurality of hafnium oxide multilayers can be interspersed among a plurality of lanthanum oxide multilayers. The hafnium oxide can comprise thermally stable, crystalline hafnium oxide, and the lanthanum oxide can comprise thermally stable, crystalline lanthanum oxide.

According to various methods, at least one monolayer of a first material is chemisorbed over a substrate, where the first material comprises a first metal. At least some of the chemisorbed first material is treated and an oxide of the first metal is formed. At least one monolayer of a second material (second metal) is chemisorbed on the first metal oxide. An oxide of the second metal is formed. One of the first and second metals comprises hafnium and the other comprises lanthanum. The first material can comprise HfCl₄, and the chemisorbed first material can be treated by exposure to H₂O to form HfO₂. The first material can comprise La(thd)₃, and the chemisorbed first material can be treated by exposure to H₂O to form La₂O₃.

Additional information regarding nanolaminates such a La₂O₃/Hf₂O₃ as high-k dielectrics can be found in US Patent Application Publication 2004/0038554-A1 entitled “Composite Dielectric Forming Methods and Composite Dielectrics,” which is herein incorporated by reference.

HfO₂/ZrO₂

The high-k dielectric can be provided by a HfO₂/ZrO₂ nanolaminate, which can be formed by atomic layer deposition of HfO₂ using a HfI₄ precursor followed by the formation of ZrO₂ on the HfO₂ layer. The HfO₂ layer thickness is controlled by repeating for a number of cycles a sequence including pulsing the HfI₄ precursor into a reaction chamber, pulsing a purging gas into the reaction chamber, pulsing a first oxygen-containing precursor into the reaction chamber, and pulsing the purging gas until the desired thickness is formed. These gate dielectrics containing HfO₂/ZrO₂ nanolaminates are thermodynamically stable such that the HfO₂/ZrO₂ nanolaminates will have minimal reaction with a silicon substrate or other structures during processing.

The layer of zirconium oxide can be formed by rapid thermal CVD at about 500° C. A nitrogen anneal between about 700° C. and about 900° C. can be performed after the layer of zirconium oxide is formed. The layer of hafnium oxide can be formed by pulsing a first oxygen-containing precursor, such as water vapor, into the reaction chamber after pulsing the HfI₄ precursor into the reaction chamber.

Additional information regarding nanolaminates such a HfO₂/ZrO₂ as high-k dielectrics can be found in US Patent Application Publication 2004/0023461-A1 entitled “Atomic Layer Deposited Nanolaminates of HfO₂/ZrO₂ films as Gate Dielectrics,” which is herein incorporated by reference.

Lanthanide Oxide/Zirconium Oxide

The high-k dielectric can be provided by a lanthanide oxide/zirconium oxide nanolaminate. According to various embodiments, the ZrO₂ is deposited by multiple cycles of reaction sequence atomic layer deposition (RS-ALD) that includes depositing a ZrI₄ precursor onto the surface of the substrate in a first pulse followed by exposure to H₂O/H₂O₂ in a second pulse, thereby forming a thin ZrO₂ layer on the surface. After depositing the ZrO₂ layer, the lanthanide oxide layer is deposited by electron beam evaporation. The composite laminate zirconium oxide/lanthanide oxide dielectric layer has a relatively high dielectric constant and can be formed in layers of nanometer dimensions.

Various embodiments provide a layer of ZrO₂, and a layer of a lanthanide oxide having a thickness of about 2–12 nm on the ZrO₂ layer. The ZrO₂ layer has a thickness of about 1–6 nm, and the composite laminate dielectric layer has a thickness of about 3–18 nm. The lanthanide oxide can include Pr₂O₃, Nd₂O₃, Sm₂O₃, Gd₂O₃, Dy₂O₃ and PrTi_(X)O_(Y). According to various embodiments, the composite laminate dielectric layer has a dielectric constant between about 12 and about 23. The ZrO₂ layer can be formed by atomic layer deposition from a ZrI₄ precursor followed by oxidation with H₂O/H₂O₂, and the lanthanide oxide layer can be formed by electron beam evaporation of a lanthanide oxide.

Additional information regarding nanolaminates such a lanthanide oxide/zirconium oxide as high-k dielectrics can be found in US Patent Application Publication 2005/0077519-A1 entitled “Lanthanide Oxide/Zirconium Oxide Atomic Layer Deposited Nanolaminate Gate Dielectrics,” which is herein incorporated by reference.

Lanthanide Oxide/Hafnium Oxide

The high-k dielectric can be provided by a lanthanide oxide/hafnium oxide nanolaminate, such as can be formed by forming a layer of hafnium oxide by atomic layer deposition and forming a layer of a lanthanide oxide by electron beam evaporation. According to various embodiments, the combined thickness of lanthanide oxide layers is limited to between about 2 nm and about 10 nm. Multi-layers of hafnium oxide can be formed, where each layer of lanthanide oxide is limited to a thickness between about 2 nm and 10 nm. Some embodiments limit the combined thickness of hafnium oxide layers to a thickness between about 2 nm and about 10 nm. The lanthanide oxide can include Pr₂O₃, Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃. The substrate temperature for the deposition can range between about 100° C. to about 150° C. The hafnium oxide can be formed using a HfI₄ precursor, and the lanthanide oxide can be formed on the layer of hafnium oxide by electron beam evaporation.

Additional information regarding nanolaminates such a lanthanide oxide/hafnium oxide as high-k dielectrics can be found in US Patent Application Publication 2005/0020017-A1 entitled “Lanthanide Oxide/Hafnium Oxide Dielectric Layers,” which is herein incorporated by reference.

Lanthanide Oxide/Hafnium Oxide

The high-k dielectric can be provided by a lanthanide oxide/hafnium oxide nanolaminate. The hafnium oxide can be formed by chemical vapor deposition and the lanthanide oxide can be formed by electron beam evaporation. Forming the layer of hafnium oxide by chemical vapor deposition using precursors that do not contain carbon permits the formation of the dielectric layer without carbon contamination. Various embodiments limit a combined thickness of lanthanide oxide layers to a thickness ranging from about 2 nm to about 10 nm. Various embodiments provide a multilayer of lanthanide oxide, with each layer of lanthanide oxide having a thickness ranging from about 2 nm to about 10 nm. Various embodiments limit a combined thickness of hafnium oxide layers to a thickness ranging from about 2 nanometers to about 10 nanometers. The lanthanide oxide can be selected from Pr₂O₃, Nd₂O₃, Sm₂O₃, Gd₂O₃, and Dy₂O₃. The substrate can be maintained at a temperature ranging from about 100° C. to about 150° C. during electron beam deposition and the substrate can be maintained at a temperature ranging from about 200° C. to about 400° C. during chemical vapor deposition. The dielectric layer can be formed by forming a layer of hafnium oxide on a substrate by chemical vapor deposition using a Hf(NO₃)₄ precursor, and forming a layer of a lanthanide oxide on the layer of hafnium oxide by electron beam evaporation.

Additional information regarding nanolaminates such a lanthanide oxide/hafnium oxide as high-k dielectrics can be found in US Patent Application Publication 2004/0262700-A1 entitled “Lanthanide Oxide/Haffium Oxide Dielectrics,” which is herein incorporated by reference.

PrO_(X)/ZrO₂

The high-k dielectric can be provided by a PrO_(X)/ZrO₂ nanolaminate. The nanolaminate layered dielectric structure is formed by depositing praseodymium by atomic layer deposition onto a substrate surface using precursor chemicals, followed by depositing zirconium onto the substrate using precursor chemicals, and repeating to form the thin laminate structure. The dielectric layer can be formed using either a reaction sequence atomic layer deposition, a metallo-organic chemical vapor deposition, or a combination thereof. The praseodymium oxide layer includes forming an amorphous oxide including Pr₆O₁₁, Pr₂O₃, PrO₃, and PrO₂, and combinations thereof. The zirconium oxide layer can include an amorphous oxide including ZrO, ZrO₂, and combinations thereof.

Each individual one of the praseodymium oxide layers can be less than or equal to two monolayers in thickness, or can be a continuous monolayer. The resulting monolayer has a root mean square surface roughness that is less than one tenth of the layer thickness. The thickness of the praseodymium oxide layer and the zirconium oxide layer can be selected to provide the dielectric structure with a dielectric constant greater than 30. The dielectric film can be formed at a temperature of less than 350° C. The dielectric film can be formed using a precursor material comprising a formula Pr(OCMe₂CH₂Me)₃.

Additional information regarding nanolaminates such a lanthanide oxide/hafnium oxide as high-k dielectrics can be found in U.S. patent application Ser. No. 11/010,766, filed Dec. 13, 2004 entitled “Hybrid ALD-CVD of Pr_(X)O_(Y)/ZrO₂ Films as Gate Dielectrics,” which is herein incorporated by reference.

Hf₃N₄/HfO₂

The high-k dielectric can be provided by a hafnium nitride (Hf₃N₄)/hafnium oxide (HfO₂) nanolaminate. At least one hafnium oxide layer and at least one hafnium nitride layer form the nanolaminate. Both the hafnium oxide and the hafnium nitride can be formed using atomic layer deposition. The dielectric layer can include an amorphous dielectric that includes HfO₂, Hf₃N₄, and combinations thereof.

The hafnium oxide layer can be comprised of a plurality of individually deposited hafnium oxide layers, where each individual one of the hafnium oxide layers is less than or equal to two monolayers in thickness. Each individual one of the hafnium oxide layers can be a continuous monolayer. Each individual one of the hafnium oxide layers can have a thickness within a range from 1.3 to 1.5 Å. The resulting dielectric layer can have a root mean square surface roughness that is less than one tenth of the layer thickness. A ratio of a thickness of hafnium oxide to a thickness of hafnium nitride can be selected to result in a dielectric constant of the dielectric film of greater than 20. Some embodiments separate the dielectric film from the substrate by a diffusion barrier. The dielectric film can be formed at a temperature less than 300° C.

Hf[(CH₃)₂]₄ can be used as a precursor and water vapor can be used as a reactant to form the hafnium oxide in a deposition process with a temperature between 250° C. to 300° C. HfCl₄ can be used as a precursor and water vapor can be used as a reactant to form the hafnium oxide in a deposition process with a temperature of approximately 300° C. Hf[(CH₃)₂]₄ can be used as a precursor and ammonia (NH₃) can be used as a reactant to form the hafnium oxide in a deposition process with a temperature of approximately 250° C. Various embodiments provide the hafnium nitride and hafnium oxide film as a continuous layer with a root mean square surface roughness of less than 10 Å and a current leakage rate of less than 5×10⁻⁷ amps per cm² at an electric field strength of 1 megavolt per cm.

Additional information regarding nanolaminates such a lanthanide oxide/hafnium oxide as high-k dielectrics can be found in U.S. patent application Ser. No. 11/063,717 filed Feb. 23, 2005 entitled “Atomic Layer Deposition of Hf₃N₄/HfO₂ Films as Gate Dielectrics,” which is herein incorporated by reference.

Zr₃N₄/ZrO₂

The high-k dielectric can be provided by a Zr₃N_(4/)ZrO₂ nanolaminate. Atomic layer deposition can be used to form at least one zirconium oxide layer and at least one zirconium nitride layer. The dielectric layer can include an amorphous dielectric that includes ZrO₂, Zr₃N₄, and combinations thereof. The zirconium oxide layer can be comprised of a plurality of individually deposited zirconium oxide layers, where each individual one of the zirconium oxide layers is less than or equal to two monolayers in thickness. Each individual one of the zirconium oxide layers can be a continuous monolayer with a step coverage of greater than 90% over 90 degree angle steps. In various embodiments, each individual one of the zirconium oxide layers has a thickness within a range from 1.3 to 1.5 Å. Some embodiments provide the dielectric layer with a root mean square surface roughness that is less than one tenth of the layer thickness. A ratio of a thickness of zirconium oxide to a thickness of zirconium nitride can be selected to result in a dielectric constant of the dielectric film of greater than 20. A diffusion barrier can separate the dielectric film from the substrate. The dielectric film can be formed at a temperature of between 275° C. to 325° C. ZrI₄ can be used as a precursor, and water vapor and hydrogen peroxide can be used as reactants to form zirconium oxide in a deposition process where the temperature is between 325° C. to 500° C. ZrCl₄ can be used as a precursor, and water vapor can be used as a reactant to form zirconium oxide in a deposition process where the temperature is approximately 300° C. Zr[(CH₃)₂]₄, can be used as a precursor and ammonia (NH₃) can be used as a reactant to form zirconium oxide in a deposition process where the temperature is approximately 250° C. The zirconium nitride and zirconium oxide film can each be a continuous layer having a root mean square surface roughness of less than 5 Å and a current leakage rate of less than 1.1×10⁻⁷ amps per cm² at an electric field strength of 1 megavolt per cm.

Additional information regarding nanolaminates such a Zr₃N₄/ZrO₂ oxide as high-k dielectrics can be found in U.S. patent application Ser. No. 11/058,563, filed Feb. 15, 2005 entitled “Atomic Layer Deposition of Zr₃N₄/ZrO₂ Films as Gate Dielectrics,” which is herein incorporated by reference.

TiO₂/CeO₂

The high-k dielectric can be provided by a TiO₂/CeO₂ nanolaminate using ALD processes.

Wafer Level

FIG. 3 illustrates a wafer 340, upon which the transistors with self aligned metal gates can be fabricated according to embodiments of the present subject matter. A common wafer size is 8 inches in diameter. However, wafers are capable of being fabricated in other sizes, and the present subject matter is not limited to wafers of a particular size. A number of dies can be formed on a wafer. A die 341 is an individual pattern, typically rectangular, on a substrate that contains circuitry to perform a specific function. A semiconductor wafer typically contains a repeated pattern of such dies containing the same functionality. A die is typically packaged in a protective casing (not shown) with leads extending therefrom (not shown) providing access to the circuitry of the die for communication and control.

System Level

FIG. 4 illustrates a simplified block diagram of a high-level organization of an electronic system that includes the transistor with the self aligned metal gate, according to various embodiments. In various embodiments, the system 450 is a computer system, a process control system or other system that employs a processor and associated memory. The electronic system 450 has functional elements, including a processor or arithmetic/logic unit (ALU) 451, a control unit 452, a memory device unit 453 and an input/output (I/O) device 454. Generally such an electronic system 450 will have a native set of instructions that specify operations to be performed on data by the processor 451 and other interactions between the processor 451, the memory device unit 453 and the I/O devices 454. The control unit 452 coordinates all operations of the processor 451, the memory device 453 and the I/O devices 454 by continuously cycling through a set of operations that cause instructions to be fetched from the memory device 453 and executed. According to various embodiments, the memory device 453 includes, but is not limited to, random access memory (RAM) devices, read-only memory (ROM) devices, and peripheral devices such as a floppy disk drive and a compact disk CD-ROM drive. As one of ordinary skill in the art will understand upon reading and comprehending this disclosure, any of the illustrated electrical components are capable of being fabricated to include a transistor with a self aligned metal gate in accordance with the present subject matter.

FIG. 5 illustrates a simplified block diagram of a high-level organization of an electronic system that includes transistors with self aligned metal gates, according to various embodiments. The system 560 includes a memory device 561 which has an array of memory cells 562, address decoder 563, row access circuitry 564, column access circuitry 565, read/write control circuitry 566 for controlling operations, and input/output circuitry 567. The memory device 561 further includes power circuitry 568, and sensors 569 for determining the state of the memory cells. The illustrated power circuitry 568 includes power supply circuitry, circuitry for providing a reference voltage, circuitry for providing the word line with pulses, and circuitry for providing the bit line with pulses. Also, as shown in FIG. 5, the system 560 includes a processor 570, or memory controller for memory accessing. The memory device receives control signals from the processor over wiring or metallization lines. The memory device is used to store data which is accessed via I/O lines. It will be appreciated by those skilled in the art that additional circuitry and control signals can be provided, and that the memory device has been simplified. At least one of the processor or memory device includes the transistor with the self aligned metal gate according to the present subject matter.

The illustration of system 560, as shown in FIG. 5, is intended to provide a general understanding of one application for the structure and circuitry of the present subject matter, and is not intended to serve as a complete description of all the elements and features of an electronic system. As one of ordinary skill in the art will understand, such an electronic system can be fabricated in single-package processing units, or even on a single semiconductor chip, in order to reduce the communication time between the processor and the memory device.

Applications containing transistors with self aligned metal gates on high-k dielectrics, as described in this disclosure, include electronic systems for use in memory modules, device drivers, power modules, communication modems, processor modules, and application-specific modules, and may include multilayer, multichip modules. Such circuitry can further be a subcomponent of a variety of electronic systems, such as a clock, a television, a cell phone, a personal computer, an automobile, an industrial control system, an aircraft, and others.

This disclosure includes several processes, circuit diagrams, and structures. The present invention is not limited to a particular process order or logical arrangement. Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement which is calculated to achieve the same purpose may be substituted for the specific embodiments shown. This application is intended to cover adaptations or variations. It is to be understood that the above description is intended to be illustrative, and not restrictive. Combinations of the above embodiments, and other embodiments, will be apparent to those of skill in the art upon reviewing the above description. The scope of the present invention should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. 

1. An integrated circuit structure, comprising: a substrate; a high-k gate dielectric over the substrate; a sacrificial carbon gate over the dielectric; an etch barrier over the sacrificial carbon gate; and carbon sidewall spacers over the etch barrier adjacent the sacrificial carbon gate.
 2. The structure of claim 1, further comprising: source and drain regions within the substrate formed using the carbon sidewall spacers to define the regions.
 3. The structure of claim 1, wherein the etch barrier includes silicon nitride.
 4. The structure of claim 1, wherein the high-k gate dielectric includes a dielectric formed using an atomic layer deposition process.
 5. The structure of claim 1, wherein the high-k gate dielectric includes a dielectric formed using an evaporated deposition process.
 6. The structure of claim 1, wherein the high-k gate dielectric includes a dielectric formed using a metal oxidizing process.
 7. The structure of claim 1, wherein the high-k gate dielectric includes a nanolaminate.
 8. An integrated circuit structure, comprising: a substrate; a gate dielectric over the substrate; a sacrificial carbon gate over the dielectric; and carbon sidewall spacers adjacent the sacrificial carbon gate.
 9. The structure of claim 8, wherein the gate dielectric includes a high-k dielectric.
 10. The structure of claim 8, wherein the carbon sidewall spacers include amorphous carbon.
 11. The structure of claim 8, further comprising source and drain regions within the substrate, wherein the source and drain regions are formed using the sidewall spacers to define the regions.
 12. An integrated circuit structure, comprising: a substrate; a high-k gate dielectric over the substrate, the high-k gate dielectric having a dielectric constant above the dielectric constant of silicon dioxide; a sacrificial carbon gate over the dielectric; an etch barrier over the sacrificial carbon; carbon sidewall spacers over the etch barrier adjacent the sacrificial carbon gate; and source and drain regions within the substrate, wherein the source and drain regions are formed using the carbon sidewall spacers to define the regions.
 13. The structure of claim 12, wherein the high-k gate dielectric includes aluminum oxide.
 14. The structure of claim 12, wherein the high-k gate dielectric includes titanium oxide.
 15. The structure of claim 12, wherein the high-k gate dielectric includes yttrium oxide.
 16. The structure of claim 12, wherein the high-k gate dielectric includes zirconium oxide.
 17. The structure of claim 12, wherein the high-k gate dielectric includes hafnium oxide.
 18. The structure of claim 12, wherein the high-k gate dielectric includes zirconium silicon oxide.
 19. The structure of claim 12, wherein the high-k gate dielectric includes lanthanide aluminum oxide.
 20. The structure of claim 12, wherein the high-k gate dielectric includes magnesium aluminum oxide.
 21. The structure of claim 12, wherein the high-k gate dielectric includes hafnium aluminum oxide.
 22. The structure of claim 12, wherein the high-k gate dielectric includes zirconium aluminum oxide.
 23. The structure of claim 12, wherein the high-k gate dielectric includes chromium titanium oxide.
 24. The structure of claim 12, wherein the high-k gate dielectric includes gadolinium oxide.
 25. The structure of claim 12, wherein the high-k gate dielectric includes zirconium oxynitride.
 26. The structure of claim 12, wherein the high-k gate dielectric includes Y—Si—O.
 27. The structure of claim 12, wherein the high-k gate dielectric includes praseodymium based lanthanum oxide.
 28. The structure of claim 12, wherein the high-k gate dielectric includes lanthanide-doped titanium oxide.
 29. The structure of claim 12, wherein the high-k gate dielectric includes hafnium silicon oxynitride.
 30. The structure of claim 12, wherein the high-k gate dielectric includes Zr—Sn—Ti—O.
 31. The structure of claim 12, wherein the high-k gate dielectric includes metal oxynitride.
 32. The structure of claim 12, wherein the high-k gate dielectric includes an oxide including zirconium and titanium.
 33. The structure of claim 12, wherein the high-k gate dielectric includes zirconium-doped tantalum oxide.
 34. The structure of claim 12, wherein the high-k gate dielectric includes hafnium oxide-silicon nitride.
 35. The structure of claim 12, wherein the high-k gate dielectric includes lanthanide oxide.
 36. The structure of claim 12, wherein the high-k gate dielectric includes titanium aluminum oxide.
 37. The structure of claim 12, wherein the high-k gate dielectric includes lanthanide hafnium oxide.
 38. The structure of claim 12, wherein the high-k gate dielectric includes hafnium tantalum oxide. 